J. Org. Chem. 2002, 67, 2723-2726
2723
A Strategy for the Construction of Caged Diols Using a Photolabile Protecting Group Weiying Lin and David S. Lawrence* Department of Biochemistry, The Albert Einstein College of Medicine, 1300 Morris Park Avenue, Bronx, New York 10461
[email protected] Received December 18, 2001
Abstract: Caged analogues of biologically active compounds have received widespread attention as temporally and spatially controlled probes of cell-based processes. Recently, a coumarin-4-ylmethyl derivative has been used to cage carboxylates, sulfonates, carbamates, and phosphates. We describe herein a synthetic strategy that furnishes photosensitive caged diols and provides an entry into the protection/photodeprotection of functionality with modest leaving group abilities.
The wide variety of roles played by metabolites, proteins, and genes in biological systems has been explored using approaches that range from simple inhibitory molecules to transgenic animals. However, these technologies are generally unable to assess the precise temporal and/or spatial influence exerted by specific biomolecules in the context of a particular biological event. For example, the role of a specific enzyme during the various stages of mitosis or at the onset of carcinogenesis in an adult animal is difficult to address with a simple dead-end inhibitor or a transgenic animal model. Photoactivatable (“caged”) analogues of biomolecules furnish a simple means to control, both spatially and temporally, biological activity with light.1 A wide variety of caged species have been described, including Ca2+, NO, metal ion indicators, and peptides. More recently, caged enzymes, such as protein kinases, protein phosphatases, proteinases, and others, have been reported.2 Unfortunately, the application of these caged species to living animals has been thwarted by the short wavelengths (